Provides page images of back issues of the core scholarly journals in the humanities, social sciences, and basic sciences from the earliest issues to within a few years of current publication. Users may browse by journal title or discipline, or may search the full-text or citations/abstracts. New issues of existing titles and new titles are added approximately on a weekly basis.

Arts & Sciences I-XV

Biological Sciences Collection

Business Collection

Ecology & Botany Collection

General Sciences Collection

Jewish Studies Collection

Language & Literature Collection

Life Sciences Collection

Music Collection

19th Century British Pamphlets

Struggles for Freedom: Southern Africa.

Provides page images of back issues of the core scholarly journals in the humanities, social sciences, and basic sciences from the earliest issues to within a few years of current publication. Users may browse by journal title or discipline, or may search the full-text or citations/abstracts. New issues of existing titles and new titles are added approximately on a weekly basis.

Ten years ago, most scholars and students relied on bulky card catalogs, printed bibliographic indices, and hardcopy books and journals. Today, much content is available electronically or online. This book examines the history of one of the first, and most successful, digital resources for scholarly communication, JSTOR. Beginning as a grant-funded project of the Andrew W. Mellon Foundation at the University of Michigan, JSTOR has grown to become a major archive of the backfiles of academic journals, and its own nonprofit organization. Roger Schonfeld begins this history by looking at JSTOR's original mission of saving storage space and thereby storage costs, a mission that expanded immediately to improving access to the literature.What role did the University play? Could JSTOR have been built without the active involvement of a foundation? Why was it seen as necessary to "spin off" the project? This case study proceeds as an organizational history of the birth and maturation of this nonprofit, which had to emerge from the original university partnership to carve its own identity. How did the grant project evolve into a successful marketplace enterprise? How was JSTOR able to serve its twofold mission of archiving its journals while also providing access to them? What has accounted for its growth? Finally, Schonfeld considers implications of the economic and organizational aspects of archiving as well as the system-wide savings that JSTOR ensures by broadly distributing costs. (source: Nielsen Book Data)9780691115313 20160528

Ten years ago, most scholars and students relied on bulky card catalogs, printed bibliographic indices, and hardcopy books and journals. Today, much content is available electronically or online. This book examines the history of one of the first, and most successful, digital resources for scholarly communication, JSTOR. Beginning as a grant-funded project of the Andrew W. Mellon Foundation at the University of Michigan, JSTOR has grown to become a major archive of the backfiles of academic journals, and its own nonprofit organization. Roger Schonfeld begins this history by looking at JSTOR's original mission of saving storage space and thereby storage costs, a mission that expanded immediately to improving access to the literature.What role did the University play? Could JSTOR have been built without the active involvement of a foundation? Why was it seen as necessary to "spin off" the project? This case study proceeds as an organizational history of the birth and maturation of this nonprofit, which had to emerge from the original university partnership to carve its own identity. How did the grant project evolve into a successful marketplace enterprise? How was JSTOR able to serve its twofold mission of archiving its journals while also providing access to them? What has accounted for its growth? Finally, Schonfeld considers implications of the economic and organizational aspects of archiving as well as the system-wide savings that JSTOR ensures by broadly distributing costs. (source: Nielsen Book Data)9780691115313 20160528

"Scholarly books are increasingly available in digital form, but the online interfaces for using these books often allow only for the browsing of PDF files. JSTOR Labs, an experimental product-development group within the not-for-profit digital library JSTOR, undertook an ideation and design process to develop new and different ways of showing scholarly books online, with the goal that this new viewing interface should be relatively simple and inexpensive to implement for any scholarly book that is already available in PDF form. This paper documents that design process, including the recommendations of a working group of scholars, publishers, and librarians convened by JSTOR Labs and the Columbia University Libraries in October 2016. The prototype monograph viewer developed through this process--called "Topicgraph"--is described herein and is freely available online at https://labs.jstor.org/topicgraph"--Abstract.

"Scholarly books are increasingly available in digital form, but the online interfaces for using these books often allow only for the browsing of PDF files. JSTOR Labs, an experimental product-development group within the not-for-profit digital library JSTOR, undertook an ideation and design process to develop new and different ways of showing scholarly books online, with the goal that this new viewing interface should be relatively simple and inexpensive to implement for any scholarly book that is already available in PDF form. This paper documents that design process, including the recommendations of a working group of scholars, publishers, and librarians convened by JSTOR Labs and the Columbia University Libraries in October 2016. The prototype monograph viewer developed through this process--called "Topicgraph"--is described herein and is freely available online at https://labs.jstor.org/topicgraph"--Abstract.

This textbook offers the first unified treatment of wave propagation in electronic and electromagnetic systems and introduces readers to the essentials of the transfer matrix method, a powerful analytical tool that can be used to model and study an array of problems pertaining to wave propagation in electrons and photons. It is aimed at graduate and advanced undergraduate students in physics, materials science, electrical and computer engineering, and mathematics, and is ideal for researchers in photonic crystals, negative index materials, left-handed materials, plasmonics, nonlinear effects, and optics. Peter Markos and Costas Soukoulis begin by establishing the analogy between wave propagation in electronic systems and electromagnetic media and then show how the transfer matrix can be easily applied to any type of wave propagation, such as electromagnetic, acoustic, and elastic waves. The transfer matrix approach of the tight-binding model allows readers to understand its implementation quickly and all the concepts of solid-state physics are clearly introduced. Markos and Soukoulis then build the discussion of such topics as random systems and localized and delocalized modes around the transfer matrix, bringing remarkable clarity to the subject. Total internal reflection, Brewster angles, evanescent waves, surface waves, and resonant tunneling in left-handed materials are introduced and treated in detail, as are important new developments like photonic crystals, negative index materials, and surface plasmons. Problem sets aid students working through the subject for the first time. (source: Nielsen Book Data)9780691130033 20170814

This textbook offers the first unified treatment of wave propagation in electronic and electromagnetic systems and introduces readers to the essentials of the transfer matrix method, a powerful analytical tool that can be used to model and study an array of problems pertaining to wave propagation in electrons and photons. It is aimed at graduate and advanced undergraduate students in physics, materials science, electrical and computer engineering, and mathematics, and is ideal for researchers in photonic crystals, negative index materials, left-handed materials, plasmonics, nonlinear effects, and optics. Peter Markos and Costas Soukoulis begin by establishing the analogy between wave propagation in electronic systems and electromagnetic media and then show how the transfer matrix can be easily applied to any type of wave propagation, such as electromagnetic, acoustic, and elastic waves. The transfer matrix approach of the tight-binding model allows readers to understand its implementation quickly and all the concepts of solid-state physics are clearly introduced. Markos and Soukoulis then build the discussion of such topics as random systems and localized and delocalized modes around the transfer matrix, bringing remarkable clarity to the subject. Total internal reflection, Brewster angles, evanescent waves, surface waves, and resonant tunneling in left-handed materials are introduced and treated in detail, as are important new developments like photonic crystals, negative index materials, and surface plasmons. Problem sets aid students working through the subject for the first time. (source: Nielsen Book Data)9780691130033 20170814

This textbook offers the first unified treatment of wave propagation in electronic and electromagnetic systems and introduces readers to the essentials of the transfer matrix method, a powerful analytical tool that can be used to model and study an array of problems pertaining to wave propagation in electrons and photons. It is aimed at graduate and advanced undergraduate students in physics, materials science, electrical and computer engineering, and mathematics, and is ideal for researchers in photonic crystals, negative index materials, left-handed materials, plasmonics, nonlinear effects, and optics. Peter Markos and Costas Soukoulis begin by establishing the analogy between wave propagation in electronic systems and electromagnetic media and then show how the transfer matrix can be easily applied to any type of wave propagation, such as electromagnetic, acoustic, and elastic waves. The transfer matrix approach of the tight-binding model allows readers to understand its implementation quickly and all the concepts of solid-state physics are clearly introduced. Markos and Soukoulis then build the discussion of such topics as random systems and localized and delocalized modes around the transfer matrix, bringing remarkable clarity to the subject. Total internal reflection, Brewster angles, evanescent waves, surface waves, and resonant tunneling in left-handed materials are introduced and treated in detail, as are important new developments like photonic crystals, negative index materials, and surface plasmons. Problem sets aid students working through the subject for the first time. (source: Nielsen Book Data)9780691130033 20170814

This textbook offers the first unified treatment of wave propagation in electronic and electromagnetic systems and introduces readers to the essentials of the transfer matrix method, a powerful analytical tool that can be used to model and study an array of problems pertaining to wave propagation in electrons and photons. It is aimed at graduate and advanced undergraduate students in physics, materials science, electrical and computer engineering, and mathematics, and is ideal for researchers in photonic crystals, negative index materials, left-handed materials, plasmonics, nonlinear effects, and optics. Peter Markos and Costas Soukoulis begin by establishing the analogy between wave propagation in electronic systems and electromagnetic media and then show how the transfer matrix can be easily applied to any type of wave propagation, such as electromagnetic, acoustic, and elastic waves. The transfer matrix approach of the tight-binding model allows readers to understand its implementation quickly and all the concepts of solid-state physics are clearly introduced. Markos and Soukoulis then build the discussion of such topics as random systems and localized and delocalized modes around the transfer matrix, bringing remarkable clarity to the subject. Total internal reflection, Brewster angles, evanescent waves, surface waves, and resonant tunneling in left-handed materials are introduced and treated in detail, as are important new developments like photonic crystals, negative index materials, and surface plasmons. Problem sets aid students working through the subject for the first time. (source: Nielsen Book Data)9780691130033 20170814